Wireless Networks Advanced Computer Networks
Feb 25, 2016
WirelessNetworks
Advanced Computer Networks
Wireless Networks Outline Terminology, WLAN types, IEEE Standards
RFID (Radio Frequency IDentification)
IEEE 802.11a/b/g/n 802.11 AP Management Functions– Association, scanning
802.11 MAC Sub-Layer– DCF
• CSMA/CA• MACAW
2Advanced Computer Networks Wireless Networks
Wireless Networks Outline 802.11 MAC Sub-Layer (cont.)
– RTS/CTS– PCF
• Beacons, DIFS, SIFS– Frame Details
• PLCP preamble and header• Address fields
– Dynamic Rate Adaptation – Frame Fragmentation
3Advanced Computer Networks Wireless Networks
Broad View of Wireless Technologies
Cellular (2G to 4G)– WiMax {long range wireless}
WiFi WSN’s Near Field CommunicationsThe focus here is on WiFi technologies and MAC layer issues!!
4Advanced Computer Networks Wireless Networks
RFID in Brief RFID uses radio waves to transfer data from an electronic tag (RFID tag or label), attached to an object, through a reader to identify and track the object.
The tag's information is stored electronically.
Some RFID tags can be read from several meters away and beyond the line of sight of the reader.
5Advanced Computer Networks Wireless Networks
RFID in Brief An RFID reader transmits an encoded radio signal to interrogate the tag.
With a small RF transmitter and receiver, the RFID tag receives the message and responds with its identification information.Many RFID tags have no battery. Instead, the tag uses the radio energy transmitted by the reader as its energy source. 6Advanced Computer Networks Wireless Networks
LAN, WLAN and WSN Terminology802.3::
Ethernet CSMA/CD802.11a/b/g/n::
WiFi CSMA/CA802.15.4::
ZigBee 802.11-basedlower data rates, lower power
Bluetooth::TDMA
- wireless Personal Area Networks (PANs) that provide secure, globally unlicensed short-range radio communication.
– Clusters with max of 8: cluster head + 7 nodesWBAN (Wireless Body Area Networks):: generally 802.15.4 or TDMA medical PANs
WSNs
7Advanced Computer Networks Wireless Networks
Elements of a Wireless Network
network infrastructure
wireless hosts laptop, PDA, smart
phone run applications may be stationary
(non-mobile) or mobile wireless does not
always mean mobility
K & R8Advanced Computer Networks Wireless Networks
Elements of a Wireless Network
network infrastructure
base station (BS) typically connected
to wired network relay - responsible
for sending packets between wired network and wireless host(s) in its “area” e.g., cell towers,
802.11 access points
K & R
9Advanced Computer Networks Wireless Networks
Wireless Local Area Networks (WLANs)
The proliferation of laptop computers and other mobile devices (PDAs and cell phones) created an obvious application level demand for wireless local area networking.
Companies jumped in, quickly developing incompatible wireless products in the 1990’s.
Industry decided to entrust standardization to IEEE committee that dealt with wired LANs – namely, the IEEE 802 committee!!
10Advanced Computer Networks Wireless Networks
IEEE 802 Standards Working Groups
Figure 1-38. The important ones are marked with *. The ones marked with are hibernating. The one marked
with † gave up.
802.15.4 ZigBee
Tanenbaum
WiMAX
11Advanced Computer Networks Wireless Networks
IEEE 802.11The following IEEE 802.11 standards exist or are in
development to support the creation of technologies for wireless local area networking:
802.11a - 54 Mbps standard, 5 GHz signaling (ratified 1999)
802.11b - 11 Mbps standard, 2.4 GHz signaling (1999) 802.11c - operation of bridge connections (moved to
802.1D) 802.11d - worldwide compliance with regulations for use of
wireless signal spectrum (2001) 802.11e - Quality of Service (QoS) support (ratified in
2005) 802.11f - Inter-Access Point Protocol recommendation for
communication between access points to support roaming clients (2003)
802.11g - 54 Mbps standard, 2.4 GHz signaling (2003) 802.11h - enhanced version of 802.11a to support
European regulatory requirements (2003) 802.11i- security improvements for the 802.11 family
(2004) 802.11j - enhancements to 5 GHz signaling to support
Japan regulatory requirements (2004) 802.11k - WLAN system management (in progress)
About.com
12Advanced Computer Networks Wireless Networks
IEEE 802.11The following IEEE 802.11 standards exist or are in development
to support the creation of technologies for wireless local area networking:
802.11m - maintenance of 802.11 family documentation 802.11n - OFDM version at 248 Mbps; MIMO version up to 600
Mbps** formally voted into the standard in September 2009! 802.11p- Wireless Access for the Vehicular Environment 802.11r - fast roaming support via Basic Service Set
transitions 802.11s - ESS mesh networking for access points 802.11t - Wireless Performance Prediction - recommendation
for testing standards and metrics 802.11u - internetworking with 3G / cellular and other forms of
external networks 802.11v - wireless network management / device configuration 802.11w - Protected Management Frames security
enhancement 802.11x- skipped (generic name for the 802.11 family) 802.11y - Contention Based Protocol for interference
avoidance
About.com
13Advanced Computer Networks Wireless Networks
Indoor10-30m
Outdoor50-200m
Mid-rangeoutdoor
200m – 4 Km
Long-rangeoutdoor
5Km – 20 Km
.056
.384
14
5-1154
2G: IS-95, CDMA, GSM
2.5G: UMTS/WCDMA, CDMA2000
802.15
802.11b
802.11a,g
3G: UMTS/WCDMA-HSPDA, CDMA2000-1xEVDO
4G: LTWE WIMAX
802.11a,g point-to-point
200 802.11n
Dat
a ra
te (M
bps)
Wireless Link Standards
14
K & RAdvanced Computer Networks Wireless Networks
Wireless Link Characteristics Differences from wired link…
Decreased signal strength: radio signal attenuates as it propagates through matter (path loss).
Interference from other sources: standardized wireless network frequencies (e.g., 2.4 GHz) shared by other devices (e.g., phone); devices (motors) interfere as well.
Multipath propagation: radio signal reflects off objects ground, arriving at destination at slightly different times. {known as multipath fading}
…. makes communication across (even a point to point) wireless link much more difficult.
K & R15Advanced Computer Networks Wireless Networks
Classification of Wireless Networks
Base Station:: all communication via an Access Point (AP) {hub topology}.
– Other nodes can be fixed or mobile.
Infrastructure Wireless:: AP is connected to the wired Internet.
16Advanced Computer Networks Wireless Networks
Classification of Wireless Networks
Ad Hoc Wireless:: wireless nodes communicate directly with one another.– Mesh Networks:: have a relatively stable
topology and usually involve multi-hop routing.
MANETs (Mobile Ad Hoc Networks) :: ad hoc nodes are mobile.– VANETs (Vehicular Ad-Hoc Networks)
• a technology that uses moving cars as nodes in a network to create a mobile network.
17Advanced Computer Networks Wireless Networks
Wireless LANs
Figure 1-36.(a) Wireless networking with a base station. (b) Ad hoc networking.
Tanenbaum
18Advanced Computer Networks Wireless Networks
Infrastructure Wireless LAN
DCC 9th Ed.Stallings
19Advanced Computer Networks Wireless Networks
Wireless Mesh Network
20Advanced Computer Networks Wireless Networks
Wireless Network Taxonomysingle hop multiple hops
infrastructure(e.g., APs)
noinfrastructure
host connects to base station (WiFi,WiMAX, cellular) which connects to larger Internet
no base station, noconnection to larger Internet (Bluetooth, ad hoc nets)
host may have torelay through severalwireless nodes to connect to larger Internet: Mesh Net
no base station, noconnection to larger Internet. May have torelay to reach other wireless nodes.MANET, VANET
K & R21Advanced Computer Networks Wireless Networks
The 802.11 Protocol Stack
Note – ordinary 802.11 products are no longer being manufactured.
Figure 4-25. Part of the 802.11 protocol stack.
Tanenbaum
802.11nOFDM SDM
22Advanced Computer Networks Wireless Networks
Media Access Control
DCC 9th Ed.Stallings
23Advanced Computer Networks Wireless Networks
IEEE 802.11 Physical Layer
Physical layer conforms to OSI (seven options)– 1997: 802.11 infrared, FHSS, DSSS {FHSS and DSSS run in the 2.4GHz
band}– 1999: 802.11a OFDM and 802.11b HR-DSSS– 2003: 802.11g OFDM– 2009: 802.11n OFDM and MIMO
802.11 Infrared– Two capacities: 1 Mbps or 2 Mbps.– Range is 10 to 20 meters and cannot penetrate walls.– Does not work outdoors.
802.11 FHSS (Frequence Hopping Spread Spectrum)– The main issue is multipath fading.– [P&D] The idea behind spread spectrum is to spread the signal over a
wider frequency to minimize the interference from other devices. – 79 non-overlapping channels, each 1 Mhz wide at low end of 2.4 GHz
ISM band.– The same pseudo-random number generator used by all stations to
start the hopping process.– Dwell time: min. time on channel before hopping (400msec).
24Advanced Computer Networks Wireless Networks
IEEE 802.11 Physical Layer 802.11 DSSS (Direct Sequence Spread Spectrum)
– The main idea is to represent each bit in the frame by multiple bits in the transmitted signal (i.e., it sends the XOR of that bit and n random bits).
– Spreads signal over entire spectrum using pseudo-random sequence (similar to CDMA see Kurose & Ross Chap 6).
– Each bit transmitted using an 11-bit chipping Barker sequence, PSK at 1Mbaud.
– This yields a capacity of 1 or 2 Mbps.
Random sequence: 0100101101011001
Data stream: 1010
XOR of the two: 1011101110101001
0
0
0
1
1
1
Figure 2.37 Example 4-bit chipping sequenceP&D slide
unique codeper sender
25Advanced Computer Networks Wireless Networks
Code Division Multiple Access (CDMA)
Used in several wireless broadcast channels (cellular and satellite) standards.
A unique “code” is assigned to each user; i.e., code set partitioning.
All users share the same frequency, but each user has its own chipping sequence (i.e., unique code) to encode data.
encoded signal = (original data) X (chipping sequence)
decoding: inner-product of encoded signal and chipping sequence
Allows multiple users to “coexist” and transmit simultaneously with minimal interference (if codes are “orthogonal”).
26Advanced Computer Networks Wireless Networks
CDMA Encode/Decode
slot 1 slot 0
d1 = -1
1 1 1 1
1- 1- 1- 1-
Zi,m= di.cmd0 = 1
1 1 1 1
1- 1- 1- 1-
1 1 1 1
1- 1- 1- 1-
1 1 11
1-1- 1- 1-
slot 0channeloutput
slot 1channeloutput
channel output Zi,m
sendercode
databits
slot 1 slot 0
d1 = -1d0 = 1
1 1 1 1
1- 1- 1- 1-
1 1 1 1
1- 1- 1- 1-
1 1 1 1
1- 1- 1- 1-
1 1 11
1-1- 1- 1-
slot 0channeloutput
slot 1channeloutputreceiver
code
receivedinput
Di = S Zi,m.cmm=1
M
M
Bit width
K & R27Advanced Computer Networks Wireless Networks
CDMA: Two-Sender Interference
K & R
28Advanced Computer Networks Wireless Networks
IEEE 802.11 Physical Layer
802.11a OFDM (Orthogonal Frequency Divisional Multiplexing)
– Compatible with European HiperLan2.– 54 Mbps in wider 5.5 GHz band transmission range
is limited.– Uses 52 FDM sub-channels (48 for data; 4 for
synchronization).– Encoding is complex ( PSM up to 18 Mbps and QAM
above this capacity).– E.g., at 54 Mbps 216 data bits encoded into into 288-
bit symbols.– More difficulty penetrating walls.** net achievable throughput in the mid-20 Mbps!!
29Advanced Computer Networks Wireless Networks
IEEE 802.11 Physical Layer 802.11b HR-DSSS (High Rate Direct
Sequence Spread Spectrum)– 11a and 11b shows a split in the standards
committee.– 11b approved and hit the market before 11a.– Up to 11 Mbps in 2.4 GHz band using 11 million
chips/sec.– Note in this bandwidth, this protocol has to deal
with interference from microwave ovens, cordless phones and garage door openers.
– Range is 7 times greater than 11a.– 11b and 11a are incompatible!!** net achievable throughput in 6 Mbps range!!
30Advanced Computer Networks Wireless Networks
IEEE 802.11 Physical Layer
802.11g OFDM (Orthogonal Frequency Division Multiplexing)
– Tries to combine the best of both 802.11a and 802.11b.
– Supports bandwidths up to 54 Mbps.– Uses 2.4 GHz frequency for greater range.– Is backward compatible with 802.11b.
Note – common for products to support 802.11a/b/g in a single NIC.
31Advanced Computer Networks Wireless Networks
Data Rate vs Distance (m)Data Rate (Mbps) 802.11b 802.11a 802.11g
1 90+ — 90+
2 75 — 75
5.5(b)/6(a/g) 60 60+ 65
9 — 50 55
11(b)/12(a/g) 50 45 50
18 — 40 50
24 — 30 45
36 — 25 35
48 — 15 25
54 — 10 20DCC 9th Ed.Stallings
32Advanced Computer Networks Wireless Networks
IEEE 802.11 Physical Layer 802.11n OFDM version at 248 Mbps
Physical Layer Changes:– Multiple-Input-Multiple-Output
(MIMO)– maximum of 600 Mbps with the use
of four spatial streams at a channel width of 40 MHz.
– Spatial Division Multiplexing (SDM) MAC Layer Changes:
– Frame aggregation into single block for transmission. 33Advanced Computer Networks Wireless Networks
IEEE 802.11 MAC Frame Format
34
DCC 9th Ed.Stallings
Larger than Ethernet frame
34Advanced Computer Networks Wireless Networks
802.11 LAN Architecture
wireless host communicates with base
station base station = access
point (AP) Basic Service Set (BSS)
(aka “cell”) in infrastructure mode contains: wireless hosts access point (AP):
base station ad hoc mode: hosts
only
BSS 1
BSS 2
Internet
hub, switchor routerAP
AP
K & R35Advanced Computer Networks Wireless Networks
802.11 Management Functions
Channel Selection Scanning Station (user) Authentication and
Association Beacon Management Power Management Mode
Beacon
BeaconReturned
ProbeSent
Adv-NetsKeating
36Advanced Computer Networks Wireless Networks
Channels and AP Association
802.11b: 2.4GHz-2.485GHz spectrum divided into 11 channels (overlapping frequencies).
– AP admin chooses frequency for AP.– Interference is possible: The channel can be same as
that chosen by a neighbor AP! Wireless nodes must associate with an AP.
– Node scans channels, listening for beacon frames containing AP’s name (SSID) and MAC address.
– Node makes choice for AP association {default is best RSSI}.
– may perform authentication [K&R Chapter 8].– will typically run DHCP to get IP address in AP’s
subnet. 37Advanced Computer Networks Wireless Networks
802.11 Overlapping Channels
802.11b/g transmission occurs on one of 11 overlapping channels in the 2.4GHz North American ISM band.
2.412
2.417
2.422 2.432 2.442 2.452 2.462 2.472 2.484
2.427 2.437 2.447 2.457 2.467
23
45
17
89
10
6 1112
1314
Adv-NetsKeating
38Advanced Computer Networks Wireless Networks
802.11: Passive/Active Scanning
AP 2AP 1
H1
BBS 2BBS 1
122
3 4
Active Scanning (1)Probe Request frame
broadcast from H1.(2)Probe Response frame sent
from APs.(3)Association Request frame
sent: H1 to selected AP. (4)Association Response frame
sent: AP to H1.
AP 2AP 1
H1
BBS 2BBS 1
12 3
1
Passive Scanning(1)beacon frames sent from
APs.(2)association Request frame
sent: H1 to selected AP. (3)association Response
frame sent: AP to H1.K & R
39Advanced Computer Networks Wireless Networks
802.11 MAC Layer Protocol In 802.11 wireless LANs, “seizing the channel” does not exist as in 802.3 wired Ethernet.
Two additional problems:– Hidden Terminal Problem– Exposed Station Problem
To deal with these two problems 802.11 supports two modes of operation:
– DCF (Distributed Coordination Function)– PCF (Point Coordination Function).
All implementations must support DCF, but PCF is optional.
40Advanced Computer Networks Wireless Networks
Figure 4-26.(a)The hidden terminal problem. (b) The exposed station problem.
802.11 Problems
Tanenbaum
41Advanced Computer Networks Wireless Networks
The Hidden Terminal Problem
Wireless stations have transmission ranges and not all stations are within radio range of each other.
Simple CSMA will not work! C transmits to B. If A “senses” the channel, it will not hear C’s transmission and falsely conclude that A can begin a transmission to B.
42Advanced Computer Networks Wireless Networks
The Exposed Station Problem
This is the inverse problem. B wants to send to C and listens to the channel.
When B hears A’s transmission, B falsely assumes that it cannot send to C.
43Advanced Computer Networks Wireless Networks
Distribute Coordination Function (DCF)
CSMA/CA (CSMA with Collision Avoidance) uses one of two modes of operation:
virtual carrier sensing physical carrier sensing
The two methods are supported by:1. MACAW (Multiple Access with Collision
Avoidance for Wireless) with virtual carrier sensing.
2. 1-persistent physical carrier sensing.
44Advanced Computer Networks Wireless Networks
Wireless LAN Protocols[Tanen pp.279-280]
MACA protocol reduces hidden and exposed terminal problems:
• Sender broadcasts a Request-to-Send (RTS) and the intended receiver sends a Clear-to-Send (CTS).
• Upon receipt of a CTS, the sender begins transmission of the frame.
• RTS,CTS help determine who else is in range or busy (Collision Avoidance). - Can a collision still occur?
45Advanced Computer Networks Wireless Networks
Wireless LAN Protocols
Figure 4-12. (a) A sending an RTS to B.(b) B responding with a CTS to A.
• MACAW added ACKs, Carrier Sense, and BEB done per stream and not per station.
Tanenbaum
46Advanced Computer Networks Wireless Networks
Virtual Channel Sensing in CSMA/CA
Figure 4-27. The use of virtual channel sensing using CSMA/CA.
C (in range of A) receives the RTS and based on information in RTS creates a virtual channel busy NAV (Network Allocation Vector).
D (in range of B) receives the CTS and creates a shorter NAV.
Tanenbaum
47Advanced Computer Networks Wireless Networks
Collision Avoidance: RTS-CTS Exchange
APA B
time
RTS(A) RTS(B)
RTS(A)
CTS(A) CTS(A)
DATA (A)
ACK(A) ACK(A)
reservation collision
NAVdefer
K & R
48Advanced Computer Networks Wireless Networks
Virtual Channel Sensing in CSMA/CA
What is the advantage of RTS/CTS?RTS is 20 bytes, and CTS is 14 bytes.
MPDU can be 2300 bytes. “virtual” implies source station sets the duration field in data frame or in RTS and CTS frames.
Stations then adjust their NAV accordingly!
49Advanced Computer Networks Wireless Networks
1-Persistent Physical Carrier Sensing
The station senses the channel when it wants to send.
If idle, the station transmits.– A wireless station does not sense the channel
while transmitting. If the channel is busy, the station defers until idle and then transmits (1-persistent).
Upon collision (no ACK received), wait a random time using binary exponential backoff (BEB).
50Advanced Computer Networks Wireless Networks
IEEE 802.11 MAC Protocol: CSMA/CA802.11 sender1 if sense channel idle for DIFS then
Transmit entire frame (no CD).2 if sense channel busy then
Choose a random backoff time.When channel is busy, counter is frozen.Timer counts down while channel idle andtransmit when timer expires.if no ACK, increase random backoff
interval, repeat 2.802.11 receiver- if frame received OK return ACK after SIFS (ACK needed
due to hidden terminal problem.)
sender receiver
DIFS
data
SIFS
ACK
K & R51Advanced Computer Networks Wireless Networks
Point Coordinated Function (PCF)
PCF uses a base station (BS) to poll other stations to see if they have frames to send.
No collisions occur. Base station sends beacon frame periodically.
Base station can tell another station to sleep to save on batteries and base station holds frames for sleeping station.
Subsequently, BS awakens sleeping node via beacon frame.
52Advanced Computer Networks Wireless Networks
DCF and PCF Co-Existence
Distributed and centralized control can co-exist using InterFrame Spacing.
SIFS (Short IFS):: the time waited between packets in an ongoing dialog (RTS,CTS,data, ACK, next frame)
PIFS (PCF IFS):: when no SIFS response, base station can issue beacon or poll.
DIFS (DCF IFS):: when no PIFS, any station can attempt to acquire the channel.
EIFS (Extended IFS):: lowest priority interval used to report bad or unknown frame. 53Advanced Computer Networks Wireless Networks
Inter-frame Spacing in 802.11
Figure 4-29. Interframe Spacing in 802.11.
Tanenbaum
54Advanced Computer Networks Wireless Networks
Basic CSMA/CA
[N. Kim]
possible collision !!
55Advanced Computer Networks Wireless Networks
802.11b Physical Layer
[N. Kim]
‘Adjust transmission rate on the fly’
56Advanced Computer Networks Wireless Networks
framecontrol duration address
1address
2address
4address
3 payload CRC
2 2 6 6 6 2 6 0 - 2312 4seq
control
802.11 Frames - Addresses
Address 2: MAC addressof wireless host or AP transmitting this frame
Address 1: MAC addressof wireless host or AP to receive this frame
Address 3: MAC addressof router interface to which AP is attached
Address 4: used only in ad hoc mode
57Advanced Computer Networks Wireless Networks
Internetrouter
APH1 R1
AP MAC addr H1 MAC addr R1 MAC addraddress 1 address 2 address 3
802.11 frame
R1 MAC addr H1 MAC addr dest. address source address
802.3 frame
802.11 Frame - Addresses
K & R58Advanced Computer Networks Wireless Networks
Type FromAPSubtype To
APMore frag WEPMore
dataPower
mgtRetry RsvdProtocolversion
2 2 4 1 1 1 1 1 11 1
duration of reserved transmission time (RTS/CTS)
frame seq # (for RDT)
frame type(RTS, CTS, ACK, data)
802.11 Frame Addresses (more)
framecontrol duration address
1address
2address
4address
3 payload CRC
2 2 6 6 6 2 6 0 - 2312 4seq
control
K & R59Advanced Computer Networks Wireless Networks
hub or switch
AP 2
AP 1
H1 BBS 2
BBS 1
802.11: Mobility within Same Subnet
router H1 remains in same IP subnet: IP address can remain same.
Switch: Which AP is associated with H1?
– Uses self-learning (Ch. 5)– Switch will see frame
from H1 and “remember” which switch port can be used to reach H1.
K & R60Advanced Computer Networks Wireless Networks
Wireless Network Details All APs (or base stations) will periodically send a beacon frame (10 to 100 times a second).
Beacon frames are also used by DCF to synchronize and handle nodes that want to sleep.
– Node sets Power management bit to indicate going to sleep and timer wakes node up for next beacon.
– The AP will buffer frames intended for a sleeping wireless client and wakeup for reception with beacon frame.
61Advanced Computer Networks Wireless Networks
Wireless Network Details AP downstream/upstream traffic performance is asymmetric.
AP has buffers for downstream/upstream queueing.
Wireless communication quality between two nodes can be asymmetric due to multipath fading.{Characterization paper shows this!}
62Advanced Computer Networks Wireless Networks
Dynamic Rate Adaptation 802.11b, g and n use dynamic rate adaptation based on frame loss (algorithms internal to wireless card at the AP).– e.g. for 802.11b choices are: 11, 5.5, 2 and 1
Mbps Standard 802.11 retries:
– 7 retries for RTS and CTS– 4 retries for Data and ACK frames
RTS/CTS may be turned off by default. [Research has shown that RTS/CTS degrades performance when hidden terminal is not an issue].
63Advanced Computer Networks Wireless Networks
6464
Node Contention
[N. Kim]
without RTS/CTS
64Advanced Computer Networks Wireless Networks
Wireless Link CharacteristicsSNR: signal-to-noise ratio larger SNR – easier to
extract signal from noise. SNR versus BER tradeoffs
given a physical layer: increase power -> increase SNR-> decrease BER.
given a SNR: choose physical layer that meets BER requirement, aiming for highest throughput.
SNR may change with mobility: dynamically adapt physical layer (modulation technique, rate).
10 20 30 40
QAM256 (8 Mbps)
QAM16 (4 Mbps)
BPSK (1 Mbps)
SNR(dB)B
ER
10-1
10-2
10-3
10-5
10-6
10-7
10-4
K & R65Advanced Computer Networks Wireless Networks
Dynamic Rate Adaptation
Mobile Node Example:1. SNR decreases, BER
increases as node moves away from base station.
2. When BER becomes too high, switch to lower transmission rate but with lower BER.
Idea:: lower maximum data rate for higher throughput.
QAM256 (8 Mbps)QAM16 (4 Mbps)BPSK (1 Mbps)
10 20 30 40SNR(dB)
BE
R
10-1
10-2
10-3
10-5
10-6
10-7
10-4
operating point
K & R
Note - Performance Anomaly paper shows there are other issues when wireless flows contend at AP !
66Advanced Computer Networks Wireless Networks
6767
Rate Adaptation versus Distance
[CARA paper]
67Advanced Computer Networks Wireless Networks
ARF – Original Rate Adaptation
68
[CARA paper]
Adapts upward after 10 successes
Advanced Computer Networks Wireless Networks
Figure 4-28 Fragmentation in 802.11
High wireless error rates long packets have less probability of being successfully transmitted.
Solution: MAC layer fragmentation with stop-and-wait protocol on the fragments.
Tanenbaum
69Advanced Computer Networks Wireless Networks
Wireless Networks Summary
Terminology, WLAN types, IEEE Standards– Infrastructure, ad hoc, MANET, Base
Station, Access Point, single and multi-hop
IEEE 802.11a/b/g/n– Differences in data rate and
transmission technologies– FHSS, DSSS, CDMA, OFDM, HR-DSSS,
MIMO
70Advanced Computer Networks Wireless Networks
Wireless Networks Summary
802.11 AP Management Functions– Association with AP, active and
passive scanning, beacon frames 802.11 MAC Sub-Layer
– Overlapping channels– Hidden terminal problem, exposed
station problem– DCF
• CSMA/CA• MACAW
71Advanced Computer Networks Wireless Networks
Wireless Networks Summary
802.11 MAC Sub-Layer (cont.)– RTS/CTS– PCF
• Beacons, DIFS, SIFS, sleeping nodes– Frame Details
• PLCP preamble and header• 3 or 4 Address fields used in 802.11
– SNR vs BER issues– Dynamic Rate Adaptation– Frame Fragmentation
72Advanced Computer Networks Wireless Networks